// Copyright (C) 2009 International Business Machines.
// All Rights Reserved.
// This code is published under the Eclipse Public License.
//
// Author:  Andreas Waechter               IBM    2009-04-02

// This file is part of the Ipopt tutorial.  It is the skeleton for
// the C++ implementation of the coding exercise problem (in AMPL
// formulation):
//
// param n := 4;
//
// var x {1..n} <= 0, >= -1.5, := -0.5;
//
// minimize obj:
//   sum{i in 1..n} (x[i]-1)^2;
//
// subject to constr {i in 2..n-1}:
//   (x[i]^2+1.5*x[i]-i/n)*cos(x[i+1]) - x[i-1] = 0;
//
// The constant term "i/n" in the constraint is supposed to be input data
//

#ifndef __TUTORIALCPP_NLP_HPP__
#define __TUTORIALCPP_NLP_HPP__

#include "IpTNLP.hpp"

using namespace Ipopt;

// This inherits from Ipopt's TNLP
class TutorialCpp_NLP: public TNLP
{
public:
   /** constructor that takes in problem data */
   TutorialCpp_NLP(
      Index         N,
      const Number* a
   );

   /** default destructor */
   virtual ~TutorialCpp_NLP();

   /**@name Overloaded from TNLP */
   //@{
   /** Method to return some info about the NLP */
   virtual bool get_nlp_info(
      Index&          n,
      Index&          m,
      Index&          nnz_jac_g,
      Index&          nnz_h_lag,
      IndexStyleEnum& index_style
   );

   /** Method to return the bounds for my problem */
   virtual bool get_bounds_info(
      Index   n,
      Number* x_l,
      Number* x_u,
      Index   m,
      Number* g_l,
      Number* g_u
   );

   /** Method to return the starting point for the algorithm */
   virtual bool get_starting_point(
      Index   n,
      bool    init_x,
      Number* x,
      bool    init_z,
      Number* z_L,
      Number* z_U,
      Index   m,
      bool    init_lambda,
      Number* lambda
   );

   /** Method to return the objective value */
   virtual bool eval_f(
      Index         n,
      const Number* x,
      bool          new_x,
      Number&       obj_value
   );

   /** Method to return the gradient of the objective */
   virtual bool eval_grad_f(
      Index         n,
      const Number* x,
      bool          new_x,
      Number*       grad_f
   );

   /** Method to return the constraint residuals */
   virtual bool eval_g(
      Index         n,
      const Number* x,
      bool          new_x,
      Index         m,
      Number*       g
   );

   /** Method to return:
    *   1) The structure of the jacobian (if "values" is NULL)
    *   2) The values of the jacobian (if "values" is not NULL)
    */
   virtual bool eval_jac_g(
      Index         n,
      const Number* x,
      bool          new_x,
      Index         m,
      Index         nele_jac,
      Index*        iRow,
      Index*        jCol,
      Number*       values
   );

   /** Method to return:
    *   1) The structure of the hessian of the lagrangian (if "values" is NULL)
    *   2) The values of the hessian of the lagrangian (if "values" is not NULL)
    */
   virtual bool eval_h(
      Index         n,
      const Number* x,
      bool          new_x,
      Number        obj_factor,
      Index         m,
      const Number* lambda,
      bool          new_lambda,
      Index         nele_hess,
      Index*        iRow,
      Index*        jCol,
      Number*       values
   );

   /** This method is called when the algorithm is complete so the TNLP can store/write the solution */
   virtual void finalize_solution(
      SolverReturn               status,
      Index                      n,
      const Number*              x,
      const Number*              z_L,
      const Number*              z_U,
      Index                      m,
      const Number*              g,
      const Number*              lambda,
      Number                     obj_value,
      const IpoptData*           ip_data,
      IpoptCalculatedQuantities* ip_cq
   );
   //@}

private:
   /**@name Methods to block default compiler methods.
    *
    * The compiler automatically generates the following three methods.
    *  Since the default compiler implementation is generally not what
    *  you want (for all but the most simple classes), we usually
    *  put the declarations of these methods in the private section
    *  and never implement them. This prevents the compiler from
    *  implementing an incorrect "default" behavior without us
    *  knowing. (See Scott Meyers book, "Effective C++")
    */
   //@{
   TutorialCpp_NLP();

   TutorialCpp_NLP(
      const TutorialCpp_NLP&
   );

   TutorialCpp_NLP& operator=(
      const TutorialCpp_NLP&
   );
   //@}

   /** @name NLP data */
   //@{
   /** Number of variables */
   Index N_;
   /** Value of constants in constraints */
   Number* a_;
   //@}
};

#endif
